Novel preparation method of human metabolites of simvastatin or lovastatin using bacterial cytochrome p450 and composition therefor

ABSTRACT

A method of producing human metabolites of simvastatin or lovastatin, and more particularly, a method of producing human metabolites of simvastatin and lovastatin by using bacterial cytochrome P450 BM3(CYP102A1) or mutants thereof, and a composition and kit therefor.

TECHNICAL FIELD

The present invention relates to a method of producing human metabolites of simvastatin and lovastatin by using bacterial cytochrome P450 BM3 (CYP102A1) or mutants thereof.

This work was supported in part by the 21C Frontier Microbial Genomics and Application Center Program of the Ministry of Education, Science & Technology of the Republic of Korea and the National Research Foundation of Korea.

1. The 21C Frontier Microbial Genomics and Application Center Program of the Ministry of Education [Project No.: MG08-0306-2-0, Title: Development of humanized bacterial monooxygenase for fine chemicals using microbial cytochrome P450 enzyme genomics]

2. The National Research Foundation of Korea (previously named, Korea Science and Engineering Foundation) [Project No.: R01-2008-000-21072-02008, Title: Development of drug lead compounds using molecular evolution techniques of CYPome]

BACKGROUND ART

Simvastatin and lovastatin are well known anti-hyperlipidemic or anti-hypercholesterolemic drugs and cholesterol lowering agent. Simvastatin is metabolized to at least four primary metabolites, namely 6′β-OH simvastatin, 6′-exomethylene simvastatin, 6′-hydroxymethyl metabolite, and 3′-OH simvastatin. Although CYP3A4 is the main enzyme involved in the primary metabolism of simvastatin, CYPs 2C8 (Tornio et al., 2005), 2C9 (Transon et al., 1996), and 2D6 (Transon et al., 1996) are also involved in the formation of simvastatin metabolites.

The extensive oxidative metabolism of lovastatin in the human liver is primarily mediated by CYP3A enzymes, particularly CYP3A4, to generate three known metabolites, namely 6′β-OH lovastatin, 3″-OH lovastatin, and 6′-exomethylene metabolites (Garcia et al., 2003; Caron et al., 2007).

After oral ingestion, simvastatin and lovastatin, which are inactive lactones, are hydrolyzed to the corresponding mvastatin and lova (Vickers et al., 1990a). This is a principal metabolite and an inhibitor of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase. This enzyme catalyzes the conversion of HMG-CoA to mevalonate, which is an early rate limiting step in the biosynthesis of cholesterol. In addition to the P450-mediated oxidation and n-oxidation processes, glucuronidation constitutes a common metabolic pathway for statins (Prueksaritanont et al., 2002). It was found that the metabolites resulting from microsomal oxidation of simvastatin (Vickers et al., 1990) and lovastatin (Vyas et al., 1990) by P450 enzymes are effective inhibitors of the HMG-CoA) reductase. Therefore, it was suggested that the metabolites may contribute to the cholesterol lowering effect of simvastatin and lovastatin. However, systematic studies of safety, efficacy, and toxicity of the metabolites have not yet been carried out. The major metabolites including 6′β-OH statins, have not been prepared by chemical synthesis previously.

Cytochrome P450 enzymes (P450s or CYPs) constitute a large family of enzymes that are remarkably diverse oxygenation catalysts found throughout nature, from archaea, bacteria, fungi, plants, animals and humans (http://drnelson.utmen.edu/CytochromeP450.html). Due to their catalytic diversity and broad substrate range, P450s are attractive as biocatalysts in the production of fine chemicals, including pharmaceuticals (Guengerich 2002; Urlacher et al., 2006; Yun et al., 2007; Lamb et al., 2007). In spite of the potential use of mammalian P450s in various biotechnology fields, they are not suitable as biocatalysts mainly because of their low stability and low catalytic activity.

If prodrugs are converted to biologically ‘active metabolites’ by human liver P450s during the drug development process (Johnson et al., 2004), the pure metabolites are required to understand the drug's efficacy, toxic effect, and pharmacokinetics. When the pure metabolites are difficult to synthesize by chemical methods, using the P450s is a useful alternative to generate the metabolites of drugs or drug candidates. Metabolite preparation has been demonstrated using human liver P450s expressed in Escherichia coli (Yun et al.,2006) and in insect cells (Rushmore et al.,2000;Vail et al.,2005), but these systems are still costly and have low productivities due to limited stabilities and slow reaction rates (Guengerich et al.,1996). It was shown that engineering bacterial P450 BM3 could produce human drug metabolites (Yun et al., 2007 and references therein; Kim 2009; Kim 2010; Park 2010). Recently, the Food and Drug Administration (FDA) modified its standards for evaluating drug toxicity, particularly with regard to the toxicity of drug metabolites. In February 2008, the FDA issued the Guidance for Industry: Safety Testing of Drug Metabolites (Food and Drug Administration, Guidance for Industry: Safety Testing of Drug Metabolites; http://www.fda.gov/downloads/Drugs/GuidanceComplianceRegulatoryInformation/Gu idances/ucm079266.pdf). According to this guide, any human drug metabolites “ . . . formed at greater than 10 percent of parent drug systemic exposure at steady state should be subject to separate safety testing, that is, by synthesis and administration to test animals (Guengerich, 2009 and references therein). The issue of human metabolites in safety testing (MIST) has presented a challenge at the early stages of drug development for the pharmaceutical industry. Some metabolites of concern can be prepared by chemical methods, but the others may not be easily prepared by the chemical methods. In the later cases, human liver microsomes, heterologously expressed human enzymes in bacteria, and purified human enzymes might be good candidates for biocatalysts to prepare human drug metabolites. However, they have several weaknesses such as low catalytic activity and low stability for industrial use to prepare the metabolites.

All the cited references are incorporated herein by reference in their entireties. The information disclosed herein is intended to assist understanding of the technical background of the present invention, and cannot be prior art.

DISCLOSURE OF INVENTION Technical Problem

The purpose of the present invention is to provide a method of producing human metabolites of simvastatin and lovastatin which cannot be produced by chemical synthesis on a mass scale, and more particularly, a method of producing human metabolites of simvastatin and lovastatin using an enzyme that stably and efficiently catalyzes a reaction thereof.

Solution to Problem

The present invention provides a method of producing human metabolites of simvastatin and lovastatin using bacterial cytochrome P450 BM3 (CYP102A1) or mutants thereof, and a composition and a kit therefor. The present invention also provides novel mutants of CYP102A1 and an isolated nucleic acid encoding the mutants.

The mutants or composition provided by the present invention can be used to produce human metabolites of simvastatin and lovastatin efficiently. While simvastatin and lovastatin are known to produce at least four and three metabolites, respectively, CYP102A1 mutants produced only two metabolites, one major (6′β-OH statin) and one minor (6′-exomethylene statin) metabolites. Thus the use of wild-type and mutant CYP102A1 is beneficial in the selective production of 6′β-OH statin and 6′-exomethylene statin.

BRIEF DESCRIPTION OF DRAWINGS

The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which:

FIG. 1 shows high-performance liquid chromatography (HPLC) chromatograms of simvastatin metabolites produced by CYP102A1 mutants (M#13 to M#17) and human CYP3A4.

FIG. 2 shows HPLC chromatograms of lovastatin metabolites produced by bacterial CYP102A1 mutants (#13 to #17) and human CYP3A4.

FIG. 3 a to FIG. 3 c show LC-MS elution profiles of simvastatin and its metabolites produced by CYP102A1 mutant #17 and human CYP3A4.

FIG. 4 a to FIG. 4 c show LC-MS elution profiles of lovastatin and its metabolites produced by CYP102A1 mutant #17 and human CYP3A4.

FIG. 5 shows absorption spectra of simvastatin and its metabolites produced by human CYP3A4 (A, B, and C) and CYP102A1 mutant #17 (D, E, and F). A and D represent 6′β-hydroxyl simvastatin; B and E represent 6′-exomethylene simvastatin; and C and F represent simvastatin.

FIG. 6 shows absorption spectra of lovastatin and its metabolites produced by human CYP3A4 (A, B, and C) and CYP102A1 mutant #17 (D, E, and F). A and D represent 6′β-hydroxyl lovastatin; B and E represent 6′-exomethylene lovastatin; and C and F represent lovastatin.

FIG. 7 shows total turnover numbers of 6′β-OH product formation by CYP102A1 mutants.

FIG. 8 shows kinetic parameters of 6′β-hydroxylation of simvastatin and lovastatin produced by CYP102A1 mutants and human CYP3A4. The 6′β-hydroxylation rates of simvastatin (A) and lovastatin (B) were measured in reaction mixtures consistingof 50 pmol CYP102A1 in 0.25 ml of 100 mM potassium phosphate buffer (pH 7.4) along with a specified amount of substrate (2 to 200 μM of statins)

FIG. 9 shows an effect of αNF on 6′β-hydroxylation of simvastatin (A) and lovastatin (B), catalyzed by CYP102A1 mutants #16, #17, and human CYP3A4.

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, the present invention will now be described more fully with reference to the accompanying drawings, in which exemplary embodiments of the invention is shown.

The present inventors have found that simvastatin or lovastatin is converted into human metabolites when wild-type CYP102A1 (Seq ID No.16, GenBank Accession Nos. J04832, P14779) and site-directed mutants thereof, which are expressed in E. coli (Tables 1 and 2), are incubated with simvastatin or lovastatin in the presence of a NADPH-generating system based on results from high-performance liquid chromatography (HPLC) chromatograms (FIGS. 1 and 2), LC-MS elution profiles (FIGS. 3 and 4), absorption spectra (FIGS. 5 and 6), and nuclear magnetic resonance (NMR) spectroscopy (Tables 3 to 7). While human CYP1A2 oxidizes simvastatin and lovastatin to produce four and three major metabolites, respectively, wild-type CYP102A1 and mutants thereof selectively produce one major 640 β-OH product and one minor 6′-exomethylene product.

A turnover number of 17 types of mutants for the oxidation of statins (production of metabolites) varied over a wide range (Table 8). Mutants #16 and 17 showed higher catalytic activity than human CYP3A4. The turnover number of mutant #17 (10 min⁻¹) was 3.3 times and 2040 times higher than those of human CYP3A4 and wild-type CYP102A1,respectively.

A total turnover number of mutant #16 was the highest and 5 to 6 times higher than that of human CYP3A4 after a 4 hour reaction and that of wild-type CYP102A1 was 0.77 and 1.9 nmol product/nmol P450 for simvastatin and lovastatin, respectively (Table 9 and FIG.7). Mutants #16 and 17 showed a significantly increased K_(cat) value of 10 min⁻¹for 6′β-hydroxylation reaction of simvastatin and lovastatin. The overall range of K_(m) values of the CYP102A1 mutants was 37 to 44 μM. Catalytic efficiencies (K_(cat)/K_(m)) of mutant #17 for 6′β-hydroxylation reaction of simvastatin and lovastatin were 0.36 and 0.46 min⁻¹μM⁻¹, respectively, which are 7 times or higher than that of human CYP3A4 (Table 10 and FIG. 8).

By using a systematic screening strategy, the inventors found new natural variants of CYP102A1 among CYP102A1s from 16 different strains of B. megaterium (Table 11). Among the total 55 substituted amino acid residues of the natural variants relative to that of CYP102A1.1, substitutions of amino acids in reductase domains (residues 473-1048) occurred at a much higher frequency than in heme domain (residues 1-472) (Tables 12 and 13). Further, the inventors prepared various chimeric proteins by exchanging the heme domain of natural variants with that of said CYP102A1 mutants and found that some chimeric proteins showed dramatically higher oxidation activity towards typical human P450 substrates, including lovastatin and simvastatin, than those of mutants in Table 2(Table 14).

Based on these experimental results, the present invention provides novel mutants of CYP102A1 and a composition for catalyzing the reaction of preparing human metabolites of simvastatin or lovastatin, the composition including wild-type CYP102A1 and/or mutant(s) of CYP102A1.

The amino acid seauece of the wild-type CYP102A1 is as follows:

(Seq ID No. 16) TIKEMPQPKT FGELKNLPLL NTDKPVQALM KIADELGEIF KFEAPGRVTR YLSSQRLIKE ACDESRFDKN LSQALKFVRD FAGDGLFTSW THEKNWKKAH NILLPSFSQQ AMKGYHAMMV DIAVQLVQKW ERLNADEHIE VPEDMTRLTL DTIGLCGFNY RFNSFYRDQP HPFITSMVRA LDEAMNKLQR ANPDDPAYDE NKRQFQEDIK VMNDLVDKII ADRKASGEQS DDLLTHMLNG KDPETGEPLD DENIRYQIIT FLIAGHETTS GLLSFALYFL VKNPHVLQKA AEEAARVLVD PVPSYKQVKQ LKYVGMVLNE ALRLWPTAPA FSLYAKEDTV LGGEYPLEKG DELMVLIPQL HRDKTIWGDD VEEFRPERFE NPSAIPQHAF KPFGNGQRAC IGQQFALHEA TLVLGMMLKH FDFEDHTNYE LDIKETLTLK PEGFVVKAKS KKIPLGGIPS PSTEQSAKKV RKKAENAHNT PLLVLYGSNM GTAEGTARDL ADIAMSKGFA PQVATLDSHA GNLPREGAVL IVTASYNGHP PDNAKQFVDW LDQASADEVK GVRYSVFGCG DKNWATTYQK VPAFIDETLA AKGAENIADR GEADASDDFE GTYEEWREHM WSDVAAYFNL DIENSEDNKS TLSLQFVDSA ADMPLAKMHG AFSTNVVASK ELQQPGSARS TRHLEIELPK EASYQEGDHL GVIPRNYEGI VNRVTARFGL DASQQIRLEA EEEKLAHLPL AKTVSVEELL QYVELQDPVT RTQLRAMAAK TVCPPHKVEL EALLEKQAYK EQVLAKRLTM LELLEKYPAC EMKFSEFIAL LPSIRPRYYS ISSSPRVDEK QASITVSVVS GEAWSGYGEY KGIASNYLAE LQEGDTITCF ISTPQSEFTL PKDPETPLIM VGPGTGVAPF RGFVQARKQL KEQGQSLGEA HLYFGCRSPH EDYLYQEELE NAQSEGIITL HTAFSRMPNQ PKTYVQHVME QDGKKLIELL DQGAHFYICG DGSQMAPAVE ATLMKSYADV HQVSEADARL WLQQLEEKGR YAKDVWAG

The present invention also provides a method of producing human metabolites of simvastatin or lovastatin, the method including reacting at least one enzyme selected from the group consisting of wild-type CYP102A1 and CYP102A1 mutants with simvastatin or lovastatin. The method may further include adding a NADPH-generating system to the reaction.

The present invention also provides a kit for producing human metabolites of simvastatin or lovastatin, the kit including at least one enzyme selected from the group consisting of wild-type CYP102A1 and CYP102A1 mutants and a NADPH-generating system. The kit may further include a reagent required for the progression of reaction.

The NADPH-generating system used for the method of producing human metabolites of simvastatin or lovastatin and the kit may be any system that is known in the art. For example, the NADPH-generating system may include glucose 6-phosphate, NADP+, and yeast glucose 6-phosphate, but is not limited thereto.

The production of human metabolites of simvastatin or lovastatin is conducted at a temperature in the range of 0 to 40° C., and preferably 30 to 40° C.

The CYP102A1 mutants may be prepared using any method that is known in the art, for example, deletion mutation (Kowalski D. et al., J. Biochem., 15, 4457), PCT method, Kunkel method, site-directed mutation, DNA shuffling, staggered extension process (StEP), and error-prone PCR.

The CYP102A1 mutants according to the present invention have an amino acid sequence of the wild-type CYP102A1 modified by natural or artificial substitution, deletion, addition, and/or insertion.

The CYP102A1 mutants according to the present invention include polypeptide having an amino acid sequence which is more than 50% similar, preferably more than 75% similar, and more particularly more than 90%, 95%, 96%, 97%, 98% or 99% similar to the sequence of wild-type CYP102A1.

The amino acid of mutants used or provided by the present invention may be substituted with an amino acid that has similar properties. Preferably, the amino acid of the mutant of CYP102A1 of the present invention may be substituted with an amino acid that has similar properties as classified below. For example, alanine (A), valine (V), leucine (L), isoleucine (I), proline (P), methionine (M), phenylalanine (F), and tryptophan (W) are nonpolar amino acids with similar properties. Glycine (G), serine(s), threonine (T), cysteine (C), tyrosine (Y), asparagine( N), and glutamine (Q) are neutral amino acids, aspartic acid (D) and glutamic acid (E) are acidic amino acids, and lysine (K), arginine (R), and histidine (H) are basic amino acids.

The CYP102A1 mutant of the present invention may include at least one substitution selected from the group consisting of a substitution at a 47th amino acid of the wild-type CYP102A1, i.e., arginine (R), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine, and tryptophan, a substitution at a 51st amino acid of the wild-type CYP102A1, i.e., tyrosine (Y), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine, and tryptophan, a substitution at a 64th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine a substitution at a 74th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine, a substitution at a 81st amino acid of the wild-type CYP102A1, i.e., phenylalanine (F), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, and tryptophan, a substitution at a 86th amino acid of the wild-type CYP102A1, i.e., leucine (L), with an amino acid selected from the group consisting of alanine, valine, isoleucine, proline, methionine, phenylalanine, and tryptophan, a substitution at a 87th amino acid of the wild-type CYP102A1, i.e., phenylalanine (F), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, and tryptophan, a substitution at a 143rd amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine, a substitution at a 188th amino acid of the wild-type CYP102A1, i.e., leucine (L), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine, a substitution at a 264th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine and a substitution at a 267th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine, and tryptophan.

The said CYP102A1 mutant may include further mutations of a substitution at a 474th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 558th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with aspartic acid, a substitution at a 664th amino acid of the wild-type CYP102A1, i.e., threonine (T), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 675th amino acid of the wild-type CYP102A1, i.e., proline (P), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, methionine, phenylalanine and tryptophan, a substitution at a 678th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of glutamic acid and aspartic acid, a substitution at a 687th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 741st amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 813rd amino acid of the wild-type CYP102A1, i.e., lysine (K), with an amino acid selected from the group consisting of glutamic acid and aspartic acid, a substitution at a 825th amino acid of the wild-type CYP102A1, i.e., arginine (R), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 836th amino acid of the wild-type CYP102A1, i.e., arginine (R), with an amino acid selected from the group consisting of lysine and histidine, a substitution at a 870th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagines, and glutamine, a substitution at a 881st amino acid of the wild-type CYP102A1, i.e., isoleucine (I), with an amino acid selected from the group consisting of alanine, valine, leucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 887th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagines, and glutamine, a substitution at a 894th amino acid of the wild-type CYP102A1, i.e., proline (P), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine, and glutamine, a substitution at a 954th amino acid of the wild-type CYP102A1, i.e., serine (S), with an amino acid selected from the group consisting of glycine, threonine, cysteine, tyrosine, asparagines, and glutamine, a substitution at a 967th amino acid of the wild-type CYP102A1, i.e., methionine (M), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, phenylalanine and tryptophan, a substitution at a 981st amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with an amino acid selected from the group consisting of lysine, arginine and histidine, a substitution at a 1008th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of aspartic acid and glutamic acid, a substitution at a 1021st amino acid of the wild-type CYP102A1, i.e., histidine (H), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine and a substitution at a 1022nd amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with an amino acid selected from the group consisting of aspartic acid and glutamic acid. Alternatively, the said CYP102A1 mutant may include further mutations of a substitution at a 473rd amino acid of the wild-type CYP102A1, i.e., lysine (K), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 474th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 546th amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with an amino acid selected from the group consisting of glutamic acid and aspartic acid, a substitution at a 599th amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with glutamic acid, a substitution at a 624th amino acid of the wild-type CYP102A1, i.e., valine (V), with an amino acid selected from the group consisting of alanine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 637th amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with glutamic acid, a substitution at a 639th amino acid of the wild-type CYP102A1, i.e., lysine (K), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 660th amino acid of the wild-type CYP102A1, i.e., glycine (G), with an amino acid selected from the group consisting of arginine, lysine and histidine, a substitution at a 664th amino acid of the wild-type CYP102A1, i.e., threonine (T), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 674th amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with an amino acid selected from the group consisting of arginine, lysine and histidine, a substitution at a 715th amino acid of the wild-type CYP102A1, i.e., threonine (T), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 716th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 741st amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 782nd amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of valine, leucine, isoleucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 813rd amino acid of the wild-type CYP102A1, i.e., lysine (K), with an amino acid selected from the group consisting of glutamic acid and aspartic acid, a substitution at a 824th amino acid of the wild-type CYP102A1, i.e., isoleucine (I), with an amino acid selected from the group consisting of alanien, valine, leucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 870th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 881st amino acid of the wild-type CYP102A1, i.e., isoleucine (I), with an amino acid selected from the group consisting of alanine, valine, leucine, proline, methionine, phenylalanine and tryptophan, a substitution at a 887th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 893rd amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with an amino acid selected from the group consisting of glycine, serine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 947th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an amino acid selected from the group consisting of lysine, arginine and histidine, a substitution at a 954th amino acid of the wild-type CYP102A1, i.e., serine (S), with an amino acid selected from the group consisting of glycine, threonine, cysteine, tyrosine, asparagine and glutamine, a substitution at a 967th amino acid of the wild-type CYP102A1, i.e., methionine (M), with an amino acid selected from the group consisting of alanine, valine, leucine, isoleucine, proline, phenylalanine and tryptophan, a substitution at a 1008th amino acid of the wild-type CYP102A1, i.e., alanine (A), with an amino acid selected from the group consisting of aspartic acid and glutamic acid and a substitution at a 1019th amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with glutamic acid.

Preferably, the CYP102A1 mutant of the present invention may include at least one substitution selected from the group consisting of a substitution at a 47th amino acid of the wild-type CYP102A1, i.e., arginine (R), with leucine (L), a substitution at a 51st amino acid of the wild-type CYP102A1, i.e., tyrosine (Y), with phenylalanine (F), a substitution at a 64th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with glycine (G), a substitution at a 74th amino acid of the wild-type CYP102A1, i.e., alanine (A), with glycine (G), a substitution at a 81st amino acid of the wild-type CYP102A1, i.e., phenylalanine (F), with isoleucine (I), a substitution at a 86th amino acid of the wild-type CYP102A1, i.e., leucine (L), with isoleucine (I), a substitution at a 87th amino acid of the wild-type CYP102A1, i.e., phenylalanine (F), with valine (V) or alanine (A), a substitution at a 143rd amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with glycine (G), a substitution at a 188th amino acid of the wild-type CYP102A1, i.e., leucine (L), with glutamine (Q), and a substitution at a 267th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with valine (V).

The said CYP102A1 mutant may include further mutations of a substitution at a 474th amino acid of the wild-type CYP102A1, i.e., alanine (A), with valine(V), a substitution at a 558th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with aspartic acid (D), a substitution at a 664th amino acid of the wild-type CYP102A1, i.e., threonine (T), with alanine (A), a substitution at a 675th amino acid of the wild-type CYP102A1, i.e., proline (P), with leucine(L), a substitution at a 678th amino acid of the wild-type CYP102A1, i.e., alanine (A), with glutamic acid (E), a substitution at a 687th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with an alanine (A), a substitution at a 741st amino acid of the wild-type CYP102A1, i.e., alanine (A), with glycine (G), a substitution at a 813rd amino acid of the wild-type CYP102A1, i.e., lysine (K), with glutamic acid (E), a substitution at a 825th amino acid of the wild-type CYP102A1, i.e., arginine (R), with serine (S), a substitution at a 836th amino acid of the wild-type CYP102A1, i.e., arginine (R), with histidine (H), a substitution at a 870th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with asparagine (N), a substitution at a 881st amino acid of the wild-type CYP102A1, i.e., isoleucine (I), with valine (V), a substitution at a 887th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with glycine (G), a substitution at a 894th amino acid of the wild-type CYP102A1, i.e., proline (P), with serine (S), a substitution at a 954th amino acid of the wild-type CYP102A1, i.e., serine (S), with asparagine (N), a substitution at a 967th amino acid of the wild-type CYP102A1, i.e., methionine (M), with valine (V), a substitution at a 981st amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with arginine (R), a substitution at a 1008th amino acid of the wild-type CYP102A1, i.e., alanine (A), with aspartic acid (D), a substitution at a 1021st amino acid of the wild-type CYP102A1, i.e., histidine (H), with tyrosine (Y), and a substitution at a 1022nd amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with glutamic acid. Alternatively, the said CYP102A1 mutant may include further mutations of a substitution at a 473rd amino acid of the wild-type CYP102A1, i.e., lysine (K), with threonine (T), a substitution at a 474th amino acid of the wild-type CYP102A1, i.e., alanine (A), with valine (V), a substitution at a 546th amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with glutamic acid (E), a substitution at a 599th amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with glutamic acid (E), a substitution at a 624th amino acid of the wild-type CYP102A1, i.e., valine (V), with leucine (L), a substitution at a 637th amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with glutamic acid (E), a substitution at a 639th amino acid of the wild-type CYP102A1, i.e., lysine (K), with alanine (A), a substitution at a 660th amino acid of the wild-type CYP102A1, i.e., glycine (G), with arginine (R), a substitution at a 664th amino acid of the wild-type CYP102A1, i.e., threonine (T), with alanine (A), a substitution at a 674th amino acid of the wild-type CYP102A1, i.e., glutamine (Q), with lysine (K), a substitution at a 715th amino acid of the wild-type CYP102A1, i.e., threonine (T), with alanine (A), a substitution at a 716th amino acid of the wild-type CYP102A1, i.e., alanine (A), with threonine (T), a substitution at a 741st amino acid of the wild-type CYP102A1, i.e., alanine (A), with glycine (G), a substitution at a 782nd amino acid of the wild-type CYP102A1, i.e., alanine (A), with valine (V), a substitution at a 813rd amino acid of the wild-type CYP102A1, i.e., lysine (K), with glutamic acid (E), a substitution at a 824th amino acid of the wild-type CYP102A1, i.e., isoleucine (I), with methionine (M), a substitution at a 870th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with asparagine (N), a substitution at a 881st amino acid of the wild-type CYP102A1, i.e., isoleucine (I), with valine (V), a substitution at a 887th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with glycine (G), a substitution at a 893rd amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with glycine (G), a substitution at a 947th amino acid of the wild-type CYP102A1, i.e., glutamic acid (E), with lysine (K), a substitution at a 954th amino acid of the wild-type CYP102A1, i.e., serine (S), with asparagine (N), and glutamine, a substitution at a 967th amino acid of the wild-type CYP102A1, i.e., methionine (M), with valine (V), a substitution at a 1008th amino acid of the wild-type CYP102A1, i.e., alanine (A), with aspartic acid (D) and a substitution at a 1019th amino acid of the wild-type CYP102A1, i.e., aspartic acid (D), with glutamic acid (E).

More preferably, the mutants of CYP102A1 of the present invention may comprise substitution mutations selected from the group consisting of F87A, A264G, F87A/A264G, R47L/Y51F, R47L/Y51F/A264G, R47L/Y51F/F87A, R47L/Y51F/F87A/A264G, A74G/F87V/L188Q, R47L/L86I/L188Q, R47L/F87V/L188Q, R47L/F87V/L188Q/E267V, R47L/L86I/L188Q/E267V, R47L/L86I/F87V/L188Q, R47L/F87V/E143G/L188Q/E267V, R47L/E64G/F87V/E143G/L188Q/E267V, R47L/F81I/F87V/E143G/L188Q/E267V, and R47L/E64G/F81I/F87V/E143G/L188Q/E267V. The said CYP102A1 mutant may include further substitutions of A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I 881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E. Alternatively, the said CYP102A1 mutant may include further mutations of K473T/A474V/Q546E/D599E/V624L/D637E/K639A/G660R/T664A/Q674K/T715A/A716T/A741G/A782V/K813E/1824M/E870N/1881V/E887G/D893G/E947K/S954N/M967V/A1008D/D1019E.

Most preferably, the mutants of CYP102A1 of the present invention may comprise substitution mutations selected from the group consisting of R47L/F81I/F87V/E143G/L188Q/E267V (M#16), R47L/E64G/F81I/F87V/E143G/L188Q/E267V (M#17), R47L/L86I/F87V/L188Q/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813 E/R825S/R836H/E870N/1881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H102 1Y/Q1022E (M#13V2), R47L/E64G/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687 A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E (M#15V3), R47L/F81I/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E (M#16V2), R47L/E64G/F81I/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E (M#17V2), and R47L/E64G/F81I/F87V/E143G/L188Q/E267V/K473T/A474V/Q546E/D599E/V624L/D637E/K639A/G660R/T664A/Q674K/T715A/A716T/A741G/A782V/K813E/I824M/E870N/I881V/E887G/D893G/E947K/S954N/M967V/A1008D/D1019E (M#17V8).

The present invention also provides isolated nucleic acid molecules encoding novel mutants of CYP102A1 described in this specification.

Protein and nucleic acid according to the present invention may be prepared using various methods known in the art. For example, protein may be prepared by genetic engineering techniques, peptide synthesis using solid-phase techniques (Merrifield, J. Am. Chem. Soc., 85:2149-2154 (1963)), or method of cleaving protein using peptidase. Protein according to the present invention may be natural protein or may be prepared by a recombination of culturing cells transformed with DNA encoding CYP102A1 or mutants thereof and collecting the protein. Protein may be prepared by inserting nucleic acid molecules encoding protein according to the present invention into an expression vector, transforming the vector into a host cell, and purifying protein expressed by the transformed host cell.

For example, the vector may be plasmid, cosmid, a virus, or phage. The host cell into which DNA in the vector is closed or expressed may be a prokaryotic cell, a yeast cell, and a eukaryotic cell. Culture conditions such as a culture medium, temperature, and pH may be selected by those of ordinary skill in the art without undue experiment. In general, principles, protocols, and techniques to maximize productivity of the culture of cells may refer to Mammalian Cell Biotechnology: a Practical Approach, M. Butler, ed. (IRL Press, 1991).

The expression and cloning vector may include a promoter that is operationally linked to a nucleic acid sequence that encodes CYP102A1 or mutants thereof inducing the synthesis of mRNA. A variety of promoters that are recognizable by host cells are known. A promoter suitable for a prokaryotic host cell may be a β-lactamase and lactose promoter system, alkali phosphatase, a tryptophan (trp) promoter system, and a hybrid promoter, for example, a tac promoter. In addition, the promoter used in bacterial systems may include a Shine-Dalgarno (S.D.) sequence operationally linked to DNA that encodes CYP102A1 mutants. A promoter suitable for a yeast host cell may include 3-phosphooglycerate kinase or other glucosidases.

The present invention will be described in further detail with reference to the following examples. These examples are for illustrative purposes only and are not intended to limit the scope of the present invention.

EXAMPLES

Simvastatin and lovastatin were obtained from Merck (Rahway, N.J.). NADPH was purchased from Sigma-Aldrich (St. Louis, Mo., USA). Other chemicals were of the highest grade commercially available.

Example 1 Construction of P450 BM3 Mutants by Site-Directed Mutagenesis

The CYP102A1 mutants used in this study were selected based on earlier work showing their increased catalytic activity toward several human substrates (Kim et al., 2008b and references therein; Park et al., 2010). Each mutant bears the amino acid substitution(s) relative to wild-type CYP102A1, as summarized in Table2.

PCR primers used to introduce BamHI/SacI restriction sites and to induce mutation are listed in Table 1. Codons for amino acid substitution are in italics and are underlined. The PCR primers were obtained from Genotech (Daejeon, Korea). Genes that encode CYP102A1 mutants were amplified from pCWBM3 by PCR primers designed to facilitate cloning into an expression vector pCWori (Dr. F. W. Dahlquist, University of California, SantaBarbara, Calif.) or pSE420 (Invitrogen) (Farinas, et al., 2001). Oligonucleotide assembly was performed by PCR using the primers listed in Table 1. The amplified genes were subsequently cloned into PCWBM3 BamHI/SacI vector at the BamHI/SacI restriction sites. These plasmids were transformed into Escherichia coli DH5αF′-IQ(Invitrogen), and this strain was also used to express the mutant CYP102A1 proteins. After mutagenesis, the presence of the desired mutations was confirmed by DNA sequencing (Genotech, Daejeon, Korea)

TABLE 1 [Table 1] Name Sequence BamHI 5′-AGC  GGA TC  C ATG ACA ATT AAA GAA  forward ATG CCT C-3′ SacI 5′-ATC GAG CTC GTA GTT TGT AT-3′ reverse R47L 5′-GCG CCT GGT CTG GTA ACG CG -3′ Y51F 5′-GTA ACG CGC  TTC  TTA TCA AGT-3′ E64G 5′-GCA TGC GAT  GGC  TCA CGC TTT-3′ A74G 5′-TAAGT CAA  GGC  CTT AAA TTT GTA  CG-3′ F81I 5′-GTA CGT GAT  ATT  GCA GGA GAC-3′ L86I 5′-GGA GAC GGG  ATT  TTT ACA AGC T-3′ F87A 5′-GAC GGG TTA  GCG  ACA AGC TGG-3′ F87V 5′-GAC GGG TTA  GTG  ACA AGC TGG-3′ E143G 5′-GAA GTA CCG  GGC  GAC ATG ACA-3′ L188Q 5′-ATG AAC AAG CAG CAG CGA GCA A-3′ A264G 5′-TTC TTA ATT GGG GGA CAC GTG-3′ E267V 5′-T GCG GGA CAC  GTG  ACA ACA AGT-3′ L86I/F87V 5′-GGA GAC GGG  ATT GTG  ACA AGC TG-3′

Primers Used to Prepare Mutants

Example 2 Expression and Purification of Wild-Type CYP102A1 and Mutants Thereof

Wild-type and mutant CYP102A1 were expressed in Escherichia coli strain DH5F′-IQ and purified as described in Kim et al., 2008b. A culture was inoculated from a single colony into 5 m of a Luria-Bertani medium supplemented with ampicillin (100 μg/ml) and grown at 37° C. This culture was inoculated into 250 ml of a Terrific Broth medium supplemented with ampicillin (100 μg/ml). The cells were grown at 37° C. with shaking at 250 rpm to an OD₆₀₀ of up to 0.8, at which gene expression was induced by the addition of isopropyl-β-D-thiogalactopyranoside to a final concentration of 0.5 mM. δ-aminolevulinic acid (0.1 mM) was also added thereto. Following induction, the culture was allowed to grow another 36 hours at 30° C. Cells were harvested by centrifugation (15 min, 5000 g, 4° C.). The cell pellet was resuspended in a TES buffer (100mM Tris-HCL, pH7.6, 500mM sucrose, 0.5 mM EDTA) and lysed by sonication (Sonicator; Misonix, Inc., Farmingdale, N.Y.). After the lysates was centrifuged at 100,000 g (90 min, 4° C.), a soluble cytosolic fraction was collected and used for the activity assay. The soluble cytosolic fraction was dialyzed from a 50 mM potassium phosphate buffer (pH 7.4) and stored at −80° C. The cytosolic fraction was used within 1 month of manufacture.

The CYP102A1 concentrations were determined from CO-difference spectra as described by Omura and Sato (1964) using ε=91 mM/cm. For all of the wild-type and mutants, a typical culture yielded 300 to 700 nM P450. The expression level of wild-type and mutant CYP102A1 was typically in the range of 1.0 to 2.0 nmol P450/mg cytosolic protein.

Several mutants with high catalytic activity for some substrates in human were selected, and the substitution sites in the mutants are shown in Table 2.

TABLE 2 BM3 Wild type and Abbreviations mutants Ref WT BM3 Wild type mutant #1 F87A Carmichael et al., 2001 mutant #2 A264G Carmichael et al., 2001 mutant #3 F87A/A264G Carmichael et al., 2001 mutant #4 R47L/Y51F Carmichael et al., 2001 mutant #5 R47L/Y51F/A264G Carmichael et al., 2001 mutant #6 R47L/Y51F/F87A Carmichael et al., 2001 mutant #7 R47L/Y51F/F87A/A264G Carmichael et al., 2001 mutant #8 A74G/F87V/L188Q Li et al., 2001 mutant #9 R47L/L86I/L188Q Kim et al., 2008a mutant #10 R47L/F87V/L188Q van Vugt-Lussenbrg et al., 2007 mutant #11 R47L/F87V/L188Q/E267V van Vugt-Lussenbrg et al., 2007 mutant #12 R47L/L86I/L188Q/E267V Kim et al., 2008 mutant #13 R47L/L86I/F87V/L188Q van Vugt-Lussenbrg et al., 2007 mutant #14 R47L/F87V/E143G/ Kim et al., 2008a L188Q/E267V mutant #15 R47L/E64G/F87V/E143G/ Kim et al., 2008a L188Q/E267V mutant #16 R47L/F81I/F87V/E143G/ Kim et al., 2008a L188Q/E267V mutant #17 R47L/E64G/F81I/F87V/ van Vugt-Lussenbrg et al., E143G/L188Q/E267V 2007

Mutants of CYP102A1 used in the Present Invention

Example 3 Oxidation of Simvastatin and Lovastatin by Wild-Type P450 BM3 and Mutants Thereof

It was examined whether CYP102A1 and mutants thereof can oxidize simvastatin and lovastatin. Typical steady-state reactions for the oxidation of simvastatin and lovastatin included 50 pmol CYP102A1 in 0.25 ml of 100 mM potassium phosphate buffer (pH 7.4) along with a specified amount of substrate. To determine the kinetic parameters of several CYP102A1 mutants, 2 to 200 μM of statins were used. An aliquot of a NADPH-generating system was used to initiate reactions (final concentrations: 10 mM glucose 6-phosphate, 0.5 mM NADP+, and 1 IU yeast glucose 6-phosphate per ml). A stock solution of statins (20 mM) was prepared in DMSO and diluted into the enzyme reactions with a final organic solvent concentration of <1% (v/v).

In the case of human CYP3A4 activity assay, a control experiment of 50 pmol P450, 100 pmol NADPH-P450 reductase (CPR), 100 pmol cytocrhome b₅, and 45 μM L-α-dilauroyl-sn-glycero-3-phosphocholine (DLPC) was used instead of 50 pmol CYP102A1. After the solution was incubated for 30 minutes at 37° C., the reaction was terminated with 2-fold of ice-cold dichloromethane.

Example 3-1 HPLC Analysis

After centrifugation of the reaction mixture, the supernatant was carefully removed and the solvent was evaporated under N₂ gas as described in Vickers et al., 1990. The products were analyzed by HPLC using a Gemini C₁₈ column (4.6 mm×150 mm, 5 μm, Phenomenex, Torrance, Calif.) with a mobile phase of acetonitrile/water (70/30, v/v) containing 2.5 mM formic acid. Eluates were detected by UV at 238 nm.

First, the ability of wild-type and a set of P450 BM3 mutants to oxidize simvastatin and lovastatin was measured at a fixed substrate concentration (100 μM). While simvastatin and lovastatin are known to produce at least four and three metabolites, respectively, CYP102A1 mutants produced only two metabolites, one major (6β-OH statin) and one minor (6′-exomethylene statin) metabolites. The metabolites were analyzed by HPLC and compared to those of human CYP3A4 (FIGS. 1 and 2). Since there is no need to comprise a separate step of the 6′β-OH statin and 6′-exomethylene statin from other products, the use of wild-type and mutant CYP102A1 is beneficial.

Example 3-2 LC-MS Analysis

For the identification of simvastatin and lovastatin metabolites, produced by P450 BM3 mutants, LC-MS analysis was conducted by comparing LC profiles and fragmentation patterns of simvastatin and lovastatin metabolites.

CYP102A1 mutants and human CYP3A4 were incubated with 100 μM of lovastatin or simvastatin at 37° C. for 30 min in the presence of an NADPH-generating system. Reactions were terminated by the addition of 2-fold ice-cold CH₂Cl₂. After centrifugation, the supernatant from each incubation was removed and evaporated to dryness. The reaction residue was reconstituted into 100 μl of mobile phase by vortex mixing and sonication for 20 sec. An aliquot (10 μl) of this solution was injected onto the LC column. LC-MS analysis was carried out on Shimadzu LCMS-2010 EV system (Shimadzu Corporation, Japan) having LCMS solution software in electro spray ionization (positive) mode. The separation was performed on a Shim-pack VP-ODS column (2.0 mm i.d.×250 mm, Shimadzu Corporation, Japan) using a mobile phase of acetonitrile and water (70:30, v/v) containing 2.5 mM formic acid at a flow rate of 0.16 ml/min. To identify the metabolites, mass spectra were recorded by electro spray ionization in positive mode. Interface and detector voltages are 4.4 kV and 1.5 kV, respectively. Nebulization gas flow was set at 1.5 l/min. Interface, curve desolvation line (CDL), and heat block temperatures are 250, 230, and 200° C., respectively.

FIG. 3 a to FIG. 3 c show LC-MS elution profiles of simvastatin and its metabolites produced by CYP102A1 mutant #17 and human CYP3A4. TIC (total ion current) profiles of the metabolites generated by human CYP3A4 (A) and CYP102A1 mutant #17 (B) are shown. The profile of the reaction samples showed peaks at 5.433 min (6′β-hydroxyl simvastatin), 14.933 min (6′-exomethylene simvastatin), and 17.100 min (simvastatin). Main peaks in mass spectra of 6′β-hydroxylated simbastatin (C and F), 6′-exomethylene simvastatin (D and G), and simvastatin (E and H) produced by human CYP3A4 (C, D, and E) and CYP102A1 mutant #17 (F, G, and H), were observed at 457, 439, and 441, respectively when calculated as [M+Na]⁺.

FIG. 4 a to FIG. 4 c show LC-MS elution profile of lovastatin and its metabolites produced by CYP102A1 mutant #17 and human CYP3A4. TIC profiles of the metabolites generated by human CYP3A4 (A) and CYP102A1 mutant #17 (B) are shown. The profile of the reaction samples showed peaks at 4.933 min (6′β-hydroxyl lovastatin), 11.367 min (6′-exomethylene lovastatin), and 13.267 min (lovastatin). The peaks in mass spectra of 6′β-hydroxylation (C and F), 6-exomethylene (D and G), and lovastatin (E and H) product by human CYP3A4 (C, D, and E) and CYP102A1 mutant #17 (F, G, and H), were observed at 443, 425, and 427, respectively, when calculated as [M+Na]⁺.

Based on the LC-MS analysis of the reactants, the production of 6′β-OH statin and 6′-exomethylene statin by CYP102A1 mutants was identified. The retention time and fragmentation pattern of the metabolites produced by CYP102A1 mutants were exactly matched to those of authentic metabolites produced by human CYP3A4.

Example 3-3 Absorption Spectrum Analysis

For the identification of simvastatin and lovastatin metabolites, produced by P450 BM3 mutants, absorption spectra of simvastatin and lovastatin metabolites produced by P450 BM3 mutants were compared with those produced by human CYP3A4. It was identified the absorption spectra were exactly matched to each other.

FIG. 5 shows absorption spectra of simvastatin and its metabolites by human CYP3A4 (A, B, and C) and CYP102A1 mutant #17 (D, E, and F). The spectra were recorded in the mobile phase composition at which they eluted from the column. A and D represent 6′β-hydroxyl simvastatin; B and E represent 6′-exomethylene simvastatin; and C and F represent simvastatin.

FIG. 6 shows absorption spectra of lovastatin and its metabolites by human CYP3A4 (A, B, and C) and CYP102A1 mutant #17 (D, E, and F). The spectra were recorded in the mobile phase composition at which they eluted from the column. A and D represent 6′β-hydroxyl lovastatin; B and E represent 6′-exomethylene lovastatin; and C and F represent lovastatin.

Example 3-4 NMR Analysis

An Agilent model 1100 HPLC system was used for the isolation of the 6′β-OH metabolites of simvastatin and lovastatin in the reaction mixtures. Semi-preparative columns were used for the isolation of 6′β-OH simvastatin (Waters Sunfire Prep C18, 5 μm, 10 mm i.d.×150 mm) and 6′β-OH lovastatin (Varian Pursuit 5 C18, 5 μm, 10 mm i.d.×250 mm) from the mixtures. The 6′β-OH simvastatin was eluted with a linear gradient (1.5%/min) of 30-90% CH₃CN after elution of 30% CH₃CN for 10 min. The metabolite fractions were collected at 18.2 min. The 6′β-OH lovastatin was eluted with a series of gradients: H₂O: CH₃CN (75:25, v/v) for 20 min; (0.5%/min) of 25-45% CH₃CN for 40 min; (4.5%/min) of 45-90% CH₃CN for 40 min; 90% CH₃CN for 10 min. The metabolite fractions were collected at 63.7 min. The flow rate was 3 ml/min for both columns and the eluates were monitored at 240 nm.

NMR experiments were performed using a Varian VNMRS 600 MHz NMR spectrometer equipped with a carbon-enhanced cryogenic probe. Chloroform-dl was used as a solvent, and chemical shifts for proton and carbon were measured in parts per million (ppm) relative to TMS. All of the one-dimensional (1D) and two-dimensional (2D) NMR experiments were performed with standard pulse sequences in VNMR (v. 2.3) library and processed with the same software. Spectral assignments were done with 2D′H-, ¹³C-NMR spectroscopy along with 2D NMR spectroscopic techniques (DQ-COSY, HSQC, HMBC). The stereochemical configurations of 6′β-OH position of both compounds were determined with 1-demensional NOESY.

Table 3 shows chemical structures of simbastatin (top left), 6′β-OH simvastatin (top right), lovastatin (bottom left), and 6′β-OH lovastatin (bottom right) for the NMR assignment.

TABLE 3

The results of NMR spectroscopy analysis are shown in Tables 4 to 7. The stereochemical configurations of 6′β-OH position of both compounds were determined with ID NOESY.

TABLE 4 Chemical shifts of Simvastatin(ppm, CDCl3) Simvastatin(Sim-6) 13C 1H HMBC(H→C) 1′-CH 36.59 1.68 C-8′a, C-2′ 2′-CH 30.61 2.37 CH3-2′a, C-3′, C-4′, C-1′, C-8′a 3′-CH 132.84 5.79 C-4a′, C-1′, C-2′ CH3-2′a 4′-CH 128.37 5.99 C-5′, C-8′a, C-2′ 5′-CH 129.72 5.51 C-6′, C-8′a, C-7′, C-4′ 6′-CH 27.25 2.44 7′-CH2 32.86 2.44, 1.95 CH3-6′a, C-5′(weak, check), C-8′, C-8a′ 8′-CH 67.92 5.37 C-6′, C-4′a 8′a-CH 37.49 2.26 C-2′, C-1′(weak) 3-CH2 38.59 2.74, 2.62 C-2, C-4 4-CH 62.75 4.38 5-CH2 36.21 1.98, 1.69 C-6 6-CH 76.24 4.61 7-CH2 32.94 1.89, 1.28 C-8, C-6, C-1′ 8-CH2 24.29 1.49, 1.37 C-7, C-6, C-1′, C-2′ 3″-CH2 32.99 1.56 CH3-2″, C-1″(carbonyl), C-4″, C-2″(q) 4″-CH3 9.33 0.83 C-3″, C-2″(q) 2′a-CH3 13.87 0.89 C-2′ 6′a-CH3 23.03 1.08 C-7′ 2″-CH3(2ea) 24.79, 24.75 1.27, 1.13 C-3″, C-1″(carbonyl), C-2″(q) 2″(quarternary C) 42.99 x 4′a(quarternary C) 131.47 x 2(Carbonyl) 170.06 x 1″(Carbonyl) 177.80 x

TABLE 5 Chemical shifts of 6′-beta-hydroxy-Simvastatin(ppm, CDCl3) 6′-beta-hydroxy-Simvastatin 13C 1H HMBC(H→C) 1′-CH 36.32 1.67 2′-CH 30.71 2.41 C-3′, C-4′ C-8′a, CH3-2′a 3′-CH 135.79 5.91 C-4′a, C-1′, C-2′ 4′-CH 127.68 5.99 C-4′a, C-5′, C-8′a, C-2′ 5′-CH 129.65 5.45 C-4′, C-7′ C-8′a 6′-CH 68.65 x 7′-CH2 42.40 2.44, 1.93 C-6′, CH3-6′a 8′-CH 69.19 5.40 C-4′a 8′a-CH 37.62 2.34 3-CH2 38.62 2.75, 2.63 C-2(carbonyl), C-4 4-CH 64.79 4.39 5-CH2 36.20 1.96, 1.69 6-CH 76.04 4.61 7-CH2 32.76 1.88, 1.28 C-6, C-5 8-CH2 24.09 1.42 C-6, C-1′, C-7 3″-CH2 33.03 1.56 C-1″(carbonyl), C-2″, C-3″, CH3-2″, CH3-4″ 4″-CH3 9.32 0.84 C-2″ 2′a-CH3 13.57 0.89 C-3′, C-1′, C-2′ 6′a-CH3 30.78 1.35 C-5′, C-6′, C-7′ 2″-CH3(2ea) 24.78, 24.76 1.14, 1.13 C-1″(carbonyl), C-2″, C-3″ 2″(quarternary C) 43.07 x 4′a(quarternary C) 133.50 x 2(Carbonyl) 169.88 x 1″(Carbonyl) 177.50 x

TABLE 6 Chemical shifts of Lovastatin(ppm, CDCl3) Lovastatin 13C 1H HMBC(H→C) 1′-CH 36.53 1.70 C-8′a, C-2′, CH3-2′a 2′-CH 30.61 2.38 C-3′, C-4′, C-8′a, CH3-2′a 3′-CH 133.05 5.79 C-4′a, C-1′, C-2′, CH3-2′a 4′-CH 128.25 6.00 C-4′a, C-5′, C-8′a, C-2′, CH3-2′a 5′-CH 129.58 5.53 C-4′, C-8′a, C-7′, C-6′ 6′-CH 27.39 2.45 C-4′a(?), C-8′, CH3-6′a 7′-CH2 32.59 1.92 C-5′, C-8′a, C-6′, CH3-6′a, C-8′ 8′-CH 67.85 5.39 C-4′a, C-6′ 8′a-CH 37.20 2.27 C-4′a 3-CH2 38.52 2.73, 2.63 C-2(carbonyl), C-4, C-5 4-CH 62.52 4.37 5-CH2 36.04 1.68, 1.97 C-6, C-4 6-CH 76.37 4.62 7-CH2 32.88 1.87, 1.29 C-6, C-1′, C-8, C-5 8-CH2 24.23 1.51, 1.39 C-6, C-1′, C-7, C-2′ 3″-CH2 26.79 1.66, 1.44 C-1″, C-2″, CH3-2″, CH3-4″ 4″-CH3 11.71 0.88 C-2″, C-3″ 2′a-CH3 13.83 0.90 3′, 1′, 2′ 6′a-CH3 22.79 1.08 5′, 7′, 6′ 2″-CH3(lea) 16.22 1.11 C-1″, C-2″, C-3″, 2″-CH 41.46 2.35 C-1″, C-3″, CH3-2″, CH3-4″ 4′a(quarternary C) 131.51 x 2(Carbonyl) 170.52 x 1″(Carbonyl) 176.92 x

TABLE 7 Chemical shifts of 6′-beta-hydroxy-Lovastatin(ppm, CDCl3) 6′-beta-hydroxy-Lovastatin 13C 1H HMBC(H→C) 1′-CH 36.19 1.69 CH3-2′a 2′-CH 30.57 2.40 C-3′, C-4′, C-1′, CH3-2′a 3′-CH 135.90 5.92 C-4′a, C-1′, C-2′(weak) 4′-CH 127.61 5.99 C-4′a, C-5′, C-8′a 5′-CH 129.68 5.46 C-4′, C-7′, C-8′a 6′-CH 68.79 x 7′-CH2 42.19 2.43, 1.90 C′6, CH3-6′a 8′-CH 68.85 5.42 8′a-CH 37.42 2.33 3-CH2 38.61 2.74, 2.62 C-2(carbonyl) 4-CH 62.80 4.38 5-CH2 36.27 1.94, 1.67 6-CH 75.99 4.61 7-CH2 32.74 1.87, 1.28 C-6 8-CH2 24.03 1.45 3″-CH2 26.85 1.66, 1.46 C-1″(carbonyl), C-2″, CH3-2″, CH3-4″ 4″-CH3 11.74 0.89 C-2″, C-3″ 2′a-CH3 13.59 0.90 C3′, C-1′, C-2′ 6′a-CH3 30.74 1.34 C-5′, C-7′, C-2′ 2″-CH3(lea) 16.29 1.12 C-1″(carbonyl), C-2″, C-3″ 2″-CH 41.40 2.37 C-1″(carbonyl), CH3-2″, CH3-4″ 4′a(quarternary C) 133.50 x 2(Carbonyl) 169.99 x 1″(Carbonyl) 176.17 x

Example 3-5 Determination of Turnover Number

Table 8 shows the formation rate of 6′β-OH products generated by 17 types of CYP102A1 mutants. Assays were performed using 100 μM simvastatin or lovastatin. Values are the mean±SD of triplicate determinations.

TABLE 8 nmol product/min/nmol P450 Simvastatin Lovastatin Enzyme 6β′-OH 6′-Exomethylene 6β′-OH 6′-Exomethylene Human 3.0 ± 0.1 0.22 ± 0.01 6.5 ± 0.3 0.43 ± 0.01 C3A4 BM3 WT 0.0049 ± 0.0017 N.D. N.D. N.D. Mutant #1 0.020 ± 0.002 N.D. 0.043 ± 0.005 N.D. #2 0.0043 ± 0.0005 0.0013 ± 0.0006 N.D. N.D. #3 0.028 ± 0.003 0.0056 ± 0.0030 0.20 ± 0.01 N.D. #4 N.D. N.D. N.D. N.D. #5 0.0024 ± 0.0010 0.0019 ± 0.0003 N.D. N.D. #6 N.D. N.D. 0.063 ± 0.049 N.D. #7 0.025 ± 0.012 0.00033 ± 0.00053 0.14 ± 0.02 N.D. #8 0.29 ± 0.02 N.D. 0.40 ± 0.03 0.084 ± 0.007 #9 0.077 ± 0.003 0.0036 ± 0.0002 0.075 ± 0.006 N.D. #10 0.046 ± 0.003 0.00028 ± 0.00068 0.22 ± 0.17 0.057 ± 0.008 #11 0.67 ± 0.02 0.071 ± 0.005 0.87 ± 0.02 0.25 ± 0.01 #12 0.85 ± 0.01 0.066 ± 0.003 1.5 ± 0.1 0.24 ± 0.01 #13 0.82 ± 0.01 0.045 ± 0.003 2.2 ± 0.1 0.24 ± 0.01 #14 2.5 ± 0.1 0.52 ± 0.01 6.1 ± 1.0 0.59 ± 0.03 #15 1.9 ± 0.1 0.43 ± 0.01 3.9 ± 0.2 0.80 ± 0.01 #16 8.5 ± 0.3 1.2 ± 0.1 12 ± 1  0.68 ± 0.03 #17 10 ± 1  1.3 ± 0.1 18 ± 1  0.52 ± 0.08 N.D., not detectable(the rate of product formation was less than 0.001 nmol product/min/nmol P450)

The turnover numbers for the entire set of the 17 mutants for the oxidation of statins (product formation) varied over a wide range. Mutants #16 and #17 showed higher activities than that of human CYP3A4. In the case of mutant #17, its turnover number (10 min⁻¹) was 3.3 and 2040-fold higher than that of human CYP3A4 and wild-type CYP102A1, respectively.

Simvastatin and lovastatin proved to be a good substrate for CYP102A1 enzymes, with high turnover numbers (up to 10 and 18 min⁻¹ for 6′β-OH product formation of simvastatin and lovastatin, respectively, in the case of mutant #17).

Example 3-6 Determination of the Total Turnover Numbers

In order to measure the total turnover numbers (TTNs; mol product/mol catalyst) of mutant CYP102A1, total 1.0 mM statin was used. The reaction was initiated by the addition of the NADPH-generating system in the presence of 500 μM substrate and incubated at 37° C. for 4 hours. After 2 hours of incubation, the 500 μM substrate was added to the reaction mixture. The formation rate of simvastatin metabolites was determined by HPLC chromatograms.

The overall range of TTNs of the CYP102A1 mutants was 150 to 210 (Table 9 and FIG. 7).

TABLE 9 Simvastatin Lovastatin P450 enzyme nmol product/nmol P450 Human CYP3A4 35 ± 5 44 ± 6 BM3 WT  0.77 ± 0.04  1.9 ± 0.6 BM3 M #16 200 ± 10 210 ± 10 BM3 M #17 150 ± 10 200 ± 10

Total turnover numbers of 6′β-OH hydroxylated product formation by CYP102A1 mutants

Mutant #16 showed the highest activity, which was 5˜6-fold higher than that of human CYP3A4 with 4 hours of incubation.

Example 3-7 Determination of Kinetic Parameter

The kinetic parameters (K_(m) and k_(cat)) were determined using nonlinear regression analysis with GraphPad PRISM software (GraphPad, San Diego, Calif.). The data was fit to the standard Michaelis-Menten equation: v=k_(cat)[E][S]/([S]+K_(m)), where the velocity of the reaction is a function of the turnover (k_(cat)), which is the rate-limiting step, the enzyme concentration ([E]), substrate concentration ([S]), and the Michaelis constant (K_(m)).

Kinetic parameters of 6′β-hydroxylation of simvastatin and lovastatin by mutants #16 and 17 that have high activity were obtained (Table 10 and FIG. 8).

TABLE 10 Simvastatin Lovastatin P450enzyme k_(cat) K_(m) k_(cat)/K_(m) k_(cat) K_(m) k_(cat)/K_(m) BM3 10 ± 1  37 ± 6 0.27 ± 0.05 14 ± 1  44 ± 9  0.32 ± 0.07 M#16 BM3 15 ± 1  42 ± 6 0.36 ± 0.6  19 ± 2  41 ± 9  0.46 ± 0.11 M#17 Human 6.6 ± 0.9 130 ± 30 0.051 ± 0.014 4.2 ± 0.5 54 ± 15 0.078 ± 0.024 CYP3A4

Kinetic Parameters of 6″β-OH Hydroxylated Product Formation by CYP102A1 Mutants

Mutants #16 and 17 showed significantly increased K_(cat) value of 10 min⁻¹ for 6′β-hydroxylation reaction of simvastatin and lovastatin, compared to that of Human CYP3A4. Human CYP3A4 exhibited K_(cat) values of 6.6 and 4.2 min⁻¹ for 6′β-hydroxylation reaction of simvastatin and lovastatin, respectively. The overall range of K_(m) values of the CYP102A1 mutants was 37 to 44 μM. Human CYP3A4 exhibited a high K_(m) value of 130 μM for 6′β-hydroxylation reaction of simvastatin. Catalytic efficiencies (K_(cat)/K_(m)) of mutant #17 for 6′β-hydroxylation reaction of simvastatin and lovastatin were 0.36 and 0.46 min⁻¹μM⁻¹, respectively, which are 7 times or higher than that of human CYP3A4.

Example 4 Acquisition of Highly Active CYP102A1 Mutants

Highly active CYP102A1 mutants were obtained by exchanging the heme domain of natural variants with that of CYP102 mutants prepared in Example 2.

Example 4 -1 Isolation and Identification of Natural Variants of CYP102A1

PCR and Cloning of Natural Variants of CYP102A1

The inventors searched and identified the natural variants of CYP102A1 by sequencing the CYP102A1 of 16 different strains of B. megaterium.

For DNA preparations, cells were grown in nutrient broth. After overnight growth at 37° C., the cells were centrifuged, washed, lysed, and enzymatically treated to remove RNA and protein. The DNA preparation was then treated with phenol-chloroform (50:50) and ethanol-precipitated. The purity was evaluated by measuring UV absorbance. The variant genes from B. megaterium were amplified by PCR using oligonucleotide primers and B. megaterium chromosomal DNA template. First, PCR was carried out in a 50 μl reaction mixture containing template plasmid, forward primer BamHI-F (5′-AGCGGATCCATGACAATTAAAGAAATGCCTC-3′) and reverse primer SacI-R (5′-ATCGAGCTCGTAGTTTGTAT-3′), dNTPs, and pfu polymerase. The PCR was carried out for 30 cycles consisting of 45 s of denaturation at 94° C., 45 s of annealing at 52° C., and 90 s of extension at 72° C. Next, PCR was carried out in a similar way by use of forward primer Sad-F (5′-ATACAAACTACGAGCTCGAT-3′) and reverse primer XhoI-R (5′-ATCCTCGAGTTACCCAGCCCACACGTC-3′). The PCR product was digested with BamHI and Sad, and ligated into the pCW ori expression vector that had previously digested with the same restriction enzymes. The amplified genes were subsequently cloned into the pCWBM3 BamHI/SacI vector at the BamHI/SacI restriction sites.

Because PCR amplification could lead to the introduction of random mutations and cloning of PCR products can fortuitously select the mutated sequences, CYP102A1 gene was PCR amplified a second time from genomic DNA and the sequences were directly determined without prior cloning. Exactly the same variations as those shown in Table 11 were again found, indicating that they were not artificially introduced during the PCR amplification.

Expression and Purification of Natural Variants of CYP102A1

Plasmids were transformed into E. coli DH5a F′-IQ cell. Overnight cultures (20 ml) grown in Luria-Bertani broth with ampicillin (100 μg/ml) selection at 37° C. were used to inoculate a 250 ml culture of Terrific broth (TB) containing 100 m/ml ampicillin, 1.0 mM thiamine, trace elements, 50 μM FeCl₃, 1mM MgCl₂, and 2.5 mM (NH₄)₂SO. Cells were grown at 37° C. and 250 rpm to an OD₆₀₀ of between 0.6-0.8. Protein expression was induced by adding 1.0 mM IPTG and 1.5 mM δ-ALA, and cultures were grown at 28° C. and 200 rpm for 50 h. The cells were harvested by centrifugation (15 min, 5,000 g, 4° C.). The cell pellet was resuspended in TES buffer [100 mM Tris-HCl (pH 7.6), 500 mM sucrose, 0.5 mM EDTA)] and lysed by sonication (Sonicator, HeatSystems Ultrasonic, Inc.). After the lysate was centrifuged at 100,000 g (90 min, 4° C.), the soluble cytosolic fraction was collected and used for the activity assay. The cytosolic fraction was dialyzed against 50 mM potassium phosphate buffer (pH 7.4) and stored at −80° C. until use. The P450 concentration was determined by Fe²⁺-CO versus Fe²⁺ difference spectra.

Among 16 different strains of B. megaterium, 12 strains have natural genetic variants of CYP102A1. As some of them shared exactly the same DNA sequences, nine different types of CYP102A1 natural variants were ultimately obtained (Table 11).

TABLE 11 Accession Number Variant Genomic Strain^(a) Name^(b) DNA 16S rRNA 16S-23S intergenic KCCM 102A1.1 (J04832)^(c) FJ917385 FJ969781 11745 IFO 12108 102A1.1 (J04832)^(c) FJ969756 FJ969774 ATCC 102A1.1 (J04832)^(c) FJ969751 FJ969767 14581 KCCM 102A1.1 (J04832)^(c) FJ969762 FJ969792 41415 KCTC 3712 102A1.2 FJ899078 FJ969764 FJ969795 KCCM 102A1.3 FJ899082 FJ969761 FJ969787 12503 ATCC 102A1.4 FJ899085 FJ969753 FJ969768 15451 ATCC 102A1.5 FJ899078 FJ969746 FJ969765 10778 KCCM 102A1.5 FJ899078 FJ969760 FJ969786 11938 KCCM 102A1.5 FJ899078 FJ969757 FJ969783 11761 KCCM 102A1.6 FJ899081 FJ969758 FJ969784 11776 KCCM 102A1.6 FJ899081 FJ969759 FJ969785 11934 ATCC 102A1.7 FJ899084 FJ969749 FJ969766 14945 ATCC 102A1.8 FJ899092 FJ969755 FJ969772 21916 KCTC 2194 102A1.8 FJ859036 FJ969763 FJ969794 ATCC 102A1.9 FJ899091 FJ969754 FJ969769 19213 ATCC QMB1551^(d) —^(e) —^(e) —^(e) 12872 Bacillus megaterium strains used in this study, and GenBank accession numbers for CYP102A1 variants, 16S rRNA, and ITS sequences between 16S-23S sequences. GenBank accession numbers (except JO4832) were assigned to nucleotide sequences determined in this study. The corresponding CYP102A1 variant gene for each strain is listed. ^(a)Strains of B. megaterium used in this study were obtained from Korean Culture Center of Microorganisms(KCCM), Korean Collection for Type Cultures(KCTC), American Type Microbiology(ATCC), and the Institute of Fermentation, Osaka(IFO). ^(b)The CYP102A1 variants were named based on the amino acid similarity (Tables 12 and 13). ^(c)Previously known as the nucleotide sequence of P450 BM3 (CYP102A1) from Bacillus megaterium. ^(d)Information regarding the CYP102A1 variant of B. megaterium QMB1551 (ATCC12872) was obtained from the Whole Genome Sequencing of (http://www.bios.niu.edu/b_megaterium/) and the variant was designated as QMB1551. We only used its genetic information to compare to those of other variants and did not study its biochemical and physical properties. ^(e)Genetic information of B. megaterium QMB1551(ATCC12872) regarding its CYP102A1 variant, 16SrRNA, and ITS was obtained from the Whole Genome Sequencing of (http://www.bios.niu.edu/b_megaterium/). Accession numbers were not provided.

The wild type CYP102A1 of B. megaterium was named as CYP102A1.1 and the CYP102A1 variants were named based on the amino acid similarity. Among the total 55 substituted amino acid residues of the natural variants relative to that of CYP102A1.1, substitutions of amino acids in reductase domains (residues 473-1049) (45 of 55, 82%) occurred at a much higher frequency than in heme domain (residues 1-472) (10 of 55, 18%) (Tables 12 and 13). Interestingly, no substitutions in the amino acid residues of the active site or substrate channel were seen among the 55 substitutions. Mutation of these key catalytic residues seems to be conserved during the evolution of the enzymes.

TABLE 12 Sequence variations of CYP102A1 variants Mutated amino Change of Domain acid nucloetide *2 *3 *4 *5 *6 *7 *8 *9 QMB1551 HD T1P A > C + HD V26I G > A + + + + + + + HD A28T G > A + + + + + + + HD V127I G > A + + + + + + + + HD A135T G > A + + + + + + + HD E207D A > C + HD A221T G > A + HD A295T G > A + + HD D369E C > A + + HD K452Q A > C + + + + + + HD T463R T > A + + + + + + HD V470E A > G + + + + + + RD K473T G > C + + + + + + RD A474V C > T + + + + + + + + + RD Q512R G > A + RD R525P C > T + RD Q546E C > G + + + + + RD E558D A > C + + + RD L589F C > A + RD A590S G > T + RD D599E C > A + + + + + + RD V624L G > T + + + + + + RD D631N G > A + RD D637E T > A + + + + + RD K639A A > T + + + + + + RD A651S G > T + RD G660R G > C + + + + + RD T664A A > G + + + + + + + + + RD Q674K C > A + + + + + RD P675L C > T + + (HD: Heme domain, RD: Reductase domain) Variations of amino acids and nucleotides in CYP102A1 variants (*2~*9) relative to CYP102A1.1 (P450 BM3) (*1) are shown by a (+) mark. Information regarding the CYP102A1 variant (designated as QMB1551) of B. megaterium QMB1551(ATCC12872) was obtained from the Whole Genome Sequencing of B. megaterium (http://www.bios.niu.edu/b_megaterium/). We only used its genetic information to compare to those of other variants. Blanks mean no change of amino acids or nucleotides.

TABLE 13 CYP102A1 Variants Mutated Change Dimain Amino acid of Nucleotide *2 *3 *4 *5 *6 *7 *8 *9 QMB1551 RD A678E C > A + + + RD E687A A > C + + + RD T715A A > G + + + + + RD A716T G > A + + + + + + RD A741G C > G + + + + + + + + + RD A782V C > T + + + + + RD A795T G > A + RD K813E A > G + + + + + + + + + RD I824M A > G + + + + + + RD R825S C > A + + RD R836H G > A + + RD E870N G > T + + + + + + + + RD I881V A > G + + + + + + + + + RD E887G A > G + + + + + + + + + RD D893G A > G + + + + + RD P894S C > T + + + RD G912S C > T + RD E947K G > A + + + + + RD S954N G > A + + + + + + + + + RD M967V G > A + + + + + + + + + RD Q970E C > G + RD M979V A > G + RD Q981R A > G + + RD A1008D C > A + + + + + + + + + RD D1019E C > A + + + + + + RD H1021Y C > T + + + RD Q1022K C > G + RD Q1022E C > A + + + RD G1039S G > A + (HD: Heme domain, RD: Reductase domain)

Example 4-2 Construction, Expression, and Purification of CYP102A1 Chimeras Derived from Reductase Domains of Natural Variants and Heme Domains of Mutants Prepared in Example 2

Combinations of heme and reductase domains were screened by an HTS system of 7-ethoxycoumarin, coumarin, phenacetin, and para-nitrophenol (p-NP), in a 96-well plate. The reaction mixtures (450 μl final reaction volume) contained 25 pmol mutant enzyme and 50 pmol natural variant enzyme, 100 mM potassium phosphate buffer (pH 7.4), an NADPH-generating system (0.5 mM NADP⁺, 10 mM glucose 6-phosphate, and 1.0 IU glucose 6-phosphate dehydrogenase ml⁻¹), and the specified amount of substrate. Substrates at concentrations of 1.0 mM, 1.0 mM, 500 μM, and 1.0 mM for 7-ethoxyresorufin, coumarin, p-NP, and phenacetin,respectively were used. The reactions were initiated by addition of a solution of an NADPH—generating system. After incubating for 30 min at 37° C., the reactions of 7-ethoxycoumarin and coumarin were terminated by addition of 100 μl of 20% trichloroacetic acid (w/v), and the mixtures were centrifuged at 3000 rpm for 5 min at 4° C. Aliquots of supernatant (50 μl) were transferred into new black 96-well plates containing 150 μl Tris-HCl (pH 9.0), and the fluorescence (Ex. 355 nm and Em. 460 nm) of these mixtures were measured in a microplate reader (Infinite M200, Tecan Trading AG, Switzerland). The reaction mixtures of p-NP were terminated by addition of 100 μL of 20% trichloroacetic acid (w/v), and the mixtures were centrifuged at 3000 rpm for 5 min at 4° C. Aliquots of supernatant (100 μl) were transferred into new 96-well plates containing 50 μl of 2M NaOH, and the hydroxylated product of p-NP was measured by a microplate reader at 510 nm. The reactions of phenacetin were quenched by addition of 500 μl Purpald solution (0.16 M in 2M NaOH), and the absorbance of the mixtures at 550 nm was measured after 30-45 min using a microplate reader. Several dimeric combinations showed higher activities than those of the parent proteins.

After combinations of the corresponding reductase domain of natural variants and the heme domain of mutants prepared in Example 2 were selected to make the chimeric proteins, the expression pCW vectors were made using BamHI/SacI and SacI/XhoI sites for the heme domain and reductase domain, respectively. All chimeras were verified by full sequencing to eliminate any possibility of mutations, insertions, or deletions. All of the chimeric proteins were expressed in E. coli DH5 F′-IQ cells and purified as described in Aldrichimica Acta 33, 28-30, 2000. Purified chimeric enzymes were characterized for human P450 enzyme activities using specific substrates.

The catalytic activities of CYP102A1 chimeric proteins of the reductase domain of the natural variant with the heme domain of highly active mutant prepared in Example 2 was determined according to the method of Example 3. Table 14 shows the catalytic activities of CYP102A1 chimeric proteins of the reductase domain of the natural variant with the heme domain of mutant prepared in Example 2, which have mutations in the active site and substrate channel. Selected combinations of natural variants (with initial V) and mutants (with initial M) used to generate chimeras are M#13V2, M#15V3, M#16V3, M#17V2 and M#17V8. Data are shown as the means±EM.

TABLE 14 nmol product/min/nmol P450 Simvastatin Lovastatin 6′- 6′- chimera 6′-OH Exomethylene 6′-OH Exomethylene M#13V2  0.45 ± 0.07 0.05 ± 0.01  0.31 ± 0.10 0.04 ± 0.01 M#15V3 11 ± 1 1.7 ± 0.3 13 ± 2 2.1 ± 0.2 M#16V2 39 ± 2 5.0 ± 0.4 45 ± 3 5.2 ± 0.4 M#17V2 42 ± 3 5.6 ± 0.6 36 ± 2 4.8 ± 0.4 M#17V8 32 ± 2 3.7 ± 0.3 36 ± 5 4.4 ± 0.5

Example 5 7,8-benzoflavone Effect on Oxidation of Statin by Mutant CYP102A1

It is known that αNF can modulate the catalytic activities of human CYP3A4 (Ueng et al., 1997). In this work, the effect of αNF on the catalytic activities of CYP102A1 mutants that had human CYP3A4 activities was examined.

Reaction mixtures consists of 50 pmol P450, 100 mM potassium phosphate buffer (pH 7.4), a NADPH-generating system, and a substrate (100 μM of simvastatin or lovastatin) in the presence of αNF (2 to 50 μM).

Products were analyzed by HPLC, as described above. In the case of human CYP3A4 activity assay, a control experiment of 50 pmol P450, 100 pmol NADPH-P450 reductase (CPR), 100 pmol cytocrhome b₅, and 45 μM DLPC was used instead of 50 pmol CYP102A1.

αNF inhibited the 6′β-hydroxylation of simvastatin and lovastatin in a concentration-dependent manner. When 50 μM of αNF was added to incubations with simvastatin and lovastatin (FIG. 9), the 6′β-hydroxylation activities of simvastatin and lovastatin by human CYP3A4 were inhibited by 42% and 69%, respectively. The 6′β-hydroxylation activities of simvastatin of CYP102A1 mutants #16 and #17 were inhibited by 44% and 77%, respectively. Those of lovastatin of CYP102A1 mutants #16 and #17 were inhibited by 48% and 76%, respectively, by αNF. This result shows that αNF can bind to the active site of CYP102A1 mutants to change their catalytic activities.

A triple CYP102A1 mutant of R47L/F87V/L188Q was reported to have an ability to metabolize typical mammalian P450s substrates such as amodiaquine, dextromethorphan, acetaminophen, testosterone, and 3,4-methylene dioxymethyl amphetamine (van Vugt-Lussenburg et al., 2007). Although the product formation of these chemicals by the triple CYP102A1 mutant were inhibited from 30 to 60% by αNF, αNF did not have a significant effect on the metabolism of acetaminophen and 3,4-methylenedioxymethylamphetamine.

The production of metabolites of simvastatin and lovastatin by chemical synthesis has never been reported. Therefore, an alternative to chemical synthesis of the metabolites is to use CYP102A1 enzymes to generate the metabolites of simvastatin and lovastatin.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the claims.

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1-18. (canceled)
 19. A composition for catalyzing a reaction for preparing human metabolites of simvastatin or lovastatin, the composition comprising: an isolated polypeptide having the amino acid sequence of wild-type CYP102A1 (SEQ ID NO:16), at least one mutant of CYP102A1, or both.
 20. The composition of claim 19, wherein the at least one mutant of CYP102A1 is a polypeptide having the amino acid sequence of SEQ ID NO:16 with at least one substitution selected from the group consisting of: substituting the arginine at amino acid position 47 with alanine (A), valine (V), leucine (L), isoleucine (I), proline (P), methionine (M), phenylalanine (F) or tryptophan (W); substituting the tyrosine at amino acid position 51 with A, V, L, I, P, M, F or W; substituting the glutamic acid at amino acid position 64 with glycine (G), serin (S), threonine (T), cysteine (C), tyrosine (Y) , asparagine (N) or glutamine (Q); substituting the alanine at amino acid position 74 with G, S, T, C, Y, N or Q; substituting the phenylalanine at amino acid position 81 with A, V, L, I, P, M or W; substituting the leucine at amino acid position 86 with A, V, I, P, M, F or W; substituting the phenylalanine at amino acid position 87 with A, V, L, I, P, M or W; substituting the glutamic acid at amino acid position 143 with G, S, T, C, Y, N or Q; substituting the leucine at amino acid position 188 with G, S, T, C, Y, N or Q; substituting the alanine at amino acid position 264 with G, S, T, C, Y, N or Q; and substituting the glutamic acid at amino acid position 267 with A, V, L, I, P, M, F or W.
 21. The composition of claim 20, wherein the at least one mutant of CYP102A1 further comprises at least one substitution selected from the group consisting of: substituting the alanine at amino acid position 474 with V, L, I, P, M, F or W; substituting the glutamic acid at amino acid position 558 with aspartic acid (D); substituting the threonine at amino acid position 664 with A, V, L, I, P, M, F or W; substituting the proline at amino acid position 675 with A, V, L, I, M, F or W; substituting the alanine at amino acid position 678 with glutamic acid (E) or D; substituting the glutamic acid at amino acid position 687 with A, V, L, I, P, M, F or W; substituting the alanine at amino acid position 741 with G, S, T, C, Y, N or Q; substituting the lysine at amino acid position 813 with E or D; substituting the arginine at amino acid position 825 with G, S, T, C, Y, N or Q; substituting the arginine at amino acid position 836 with lysine (K) or histidine (H); substituting the glutamic acid at amino acid position 870 with G, S, T, C, Y, N or Q; substituting the isoleucine at amino acid position 881 with A, V, L, P, M, F or W; substituting the glutamic acid at amino acid position 887 with G, S, T, C, Y, N or Q; substituting the proline at amino acid position 894 with G, S, T, C, Y, N or Q; substituting the serine at amino acid position 954 with G, T, C, Y, N or Q; substituting the methionine at amino acid position 967 with A, V, L, I, P, F or W; substituting the glutamine at amino acid position 981 with R, K or H; substituting the alanine at amino acid position 1008 with D or E; substituting the histidine at amino acid position 1021 with G, S, T, C, Y, N or Q; and substituting the glutamine at amino acid position 1022 with D or E.
 22. The composition of claim 20, wherein the at least one mutant of CYP102A1 comprises at least one substitution selected from the group consisting of: substituting the arginine at amino acid position 47 with L; substituting the tyrosine at amino acid position 51 with F; substituting the glutamic acid at amino acid position 64 with G; substituting the alanine at amino acid position 74 with G; substituting the phenylalanine at amino acid position 81 with I; substituting the leucine at amino acid position 86 with I; substituting the phenylalanine at amino acid position 87 with A or V; substituting the glutamic acid at amino acid position 143 with G; substituting the leucine at amino acid position 188 with Q; substituting the alanine at amino acid position 264 with G; and substituting the glutamic acid at amino acid position 267 with V.
 23. The composition of claim 22, wherein the at least one mutant of CYP102A1 further comprises at least one substitution selected from the group consisting of: substituting the alanine at amino acid position 474 with V; substituting the glutamic acid at amino acid position 558 with D; substituting the threonine at amino acid position 664 with A; substituting the proline at amino acid position 675 with L; substituting the alanine at amino acid position 678 with E; substituting the glutamic acid at amino acid position 687 with A; substituting the alanine at amino acid position 741 with G; substituting the lysine at amino acid position 813 with E; substituting the arginine at amino acid position 825 with S; substituting the arginine at amino acid position 836 with H; substituting the glutamic acid at amino acid position 870 with N; substituting the isoleucine at amino acid position 881 with V; substituting the glutamic acid at amino acid position 887 with G; substituting the proline at amino acid position 894 with S; substituting the serine at amino acid position 954 with N; substituting the methionine at amino acid position 967 with V; substituting the glutamine at amino acid position 981 with R; substituting the alanine at amino acid position 1008 with D; substituting the histidine at amino acid position 1021 with Y; and substituting the glutamine at amino acid position 1022 with E.
 24. The composition of claim 22, wherein the at least one mutant of CYP102A1 further comprises at least one substitution selected from the group consisting of: substituting the lysine at amino acid position 473 with T substituting the alanine at amino acid position 474 with V; substituting the glutamine at amino acid position 546 with E; substituting the aspartic acid at amino acid position 599 with E; substituting the valine at amino acid position 624 with L; substituting the aspartic acid at amino acid position 637 with E; substituting the lysine at amino acid position 639 with A; substituting the glycine at amino acid position 660 with R; substituting the threonine at amino acid position 664 with A; substituting the glutamine at amino acid position 674 with K; substituting the threonine at amino acid position 715 with A; substituting the alanine at amino acid position 716 with T; substituting the alanine at amino acid position 741 with G; substituting the alanine acid at amino acid position 782 with V; substituting the lysine at amino acid position 813 with E; substituting the isoleucine at amino acid position 824 with M; substituting the glutamic acid at amino acid position 870 with N; substituting the isoleucine at amino acid position 881 with V; substituting the glutamic acid at amino acid position 887 with G; substituting the aspartic acid at amino acid position 893 with G; substituting the glutamic acid at amino acid position 947 with K; substituting the serine at amino acid position 954 with N; substituting the methionine at amino acid position 967 with V; substituting the alanine at amino acid position 1008 with D; and substituting the aspartic acid at amino acid position 1019 with E.
 25. The composition of claim 20, wherein the at least one mutant of CYP102A1 further comprises at least one substitution selected from the group consisting of: substituting the lysine at amino acid position 473 with G, S, T, C, Y, N or Q; substituting the alanine at amino acid position 474 with V, L, I, P, M, F or W; substituting the glutamine at amino acid position 546 with D or E; substituting the aspartic acid at amino acid position 599 with E; substituting the valine at amino acid position 624 with A, L, I, P, M, F or W; substituting the aspartic acid at amino acid position 637 with E; substituting the lysine at amino acid position 639 with A, V, L, I, P, M, F or W; substituting the glycine at amino acid position 660 with Arginine (R), K or H; substituting the threonine at amino acid position 664 with A, V, L, I, P, M, F or W; substituting the glutamine at amino acid position 674 with R, K or H; substituting the threonine at amino acid position 715 with A, V, L, I, P, M, F or W; substituting the alanine at amino acid position 716 with G, S, T, C, Y, N or Q; substituting the alanine at amino acid position 741 with G, S, T, C, Y, N or Q; substituting the alanine at amino acid position 782 with V, L, I, P, M, F or W; substituting the lysine at amino acid position 813 with D or E; substituting the isoleucine at amino acid position 824 with A, V, L, I, P, M, F or W; substituting the glutamic acid at amino acid position 870 with G, S, T, C, Y, N or Q; substituting the isoleucine at amino acid position 881 with A, V, L, P, M, F or W; substituting the glutamic acid at amino acid position 887 with G, S, T, C, Y, N or Q; substituting the aspartic acid at amino acid position 893 with G, S, T, C, Y, N or Q; substituting the glutamic acid at amino acid position 947 with R, K or H; substituting the serine at amino acid position 954 with G, T, C, Y, N or Q; substituting the methionine at amino acid position 967 with A, V, L, I, P, M, F or W; substituting the alanine at amino acid position 1008 with D or E; and substituting the aspartic acid at amino acid position 1019 with E.
 26. The composition of claim 20, wherein the at least one mutant of CYP102A1 comprises one or more substitutions selected from the group consisting of: F87A, A264G, F87A/A264G, R47L/Y51F, R47L/Y51F/A264G, R47L/Y51F/F87A, R47L/Y51F/F87A/A264G, A74G/F87V/L188Q, R47L/L86I/L188Q, R47L/F87V/L188Q, R47L/F87V/L188Q/E267V, R47UL86I/L88Q/E267V, R47UL861/F87V/L188Q, R47L/F87V/E143G/L188Q/E267V, R47L/E64G/F87V/E143G/L188Q/E267V, R47L/F81I/F87V/E143G/L188Q/E267V, and R47L/E64G/F81I/F87V/E143G/L188Q/E267V.
 27. The composition of claim 26, wherein the at least one mutant of CYP102A1 further comprises one or more substitutions selected from the group consisting of: A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E8 87G/P894S/S954N/M967V/Q981 R/A1008D/H1021Y/Q1022E; and K473T/A474V/Q 546 E/D599EN624 L/D637E/K639A/G660R/T664A/Q674K/T715A/A716T/A 741G/A782V/K813E/I824M/E870N/I881V/E887G/D893G/E947K/S954N/M967V/A1008D/D 1019E.
 28. The composition of claim 19, wherein the at least one mutant of CYP102A1 comprises one or more substitutions selected from the group consisting of: R47L/F81I/F87V/E143G/L188Q/E267V (M#16); R47L/E64G/F81I/F87V/E143G/L188Q/E267V (M#17); R47L/L86I/F87V/L188Q/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q102 2E (M#13V2); R47L/E64G/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E (M#15V3); R47L/F81I/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E (M#16V2); R47L/E64G/F81I/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E 687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1 008D/H1021Y/Q1022E (M#17V2); and R47L/E64G/F81I/F87V/E143G/L188Q/E267V/K473T/A474V/Q546E/D599E/V624L/D637E/K639A/G660R/T664A/Q674K/T715A/A716T/A741G/A782V/K813E/I824M/E870N/I8 81V/E887G/D893G/E947K/S954N/M967V/A1008D/D1019E (M#17V8).
 29. A mutant of CYP102A1 comprising at least one substitution selected from the group consisting of substitutions listed in claim 20, and further comprising one or more substitutions listed in claim 21 or one or more substitutions listed in claim
 25. 30. A mutant of CYP102A1 comprising at least one substitution selected from the group consisting of substitutions listed in claim 22, and further comprising one or more substitutions listed in claim 23 or one or more substitutions listed in claim
 24. 31. A mutant of CYP102A1, wherein the mutant comprises amino acid substitutions selected from the group consisting of: F87A, A264G, F87A/A264G, R47L/Y51F, R47L/Y51F/A264G, R47L/Y51F/F87A, R47L/Y51F/F87A/A264G, A74G/F87V/L188Q, R47L/L86I/L188Q, R47L/F87V/L188Q, R47L/F87V/L188Q/E267V, R47L/L86I/L188Q/E267V, R47UL86I/F87V/L188Q, R47L/F87V/E143G/L188Q/E267V, R47L/E64G/F87V/E143G/L188Q/E267V, R47L/F81I/F87V/E143G/L188Q/E267V, and R47L/E64G/F81I/F87V/E143G/L188Q/E267V, and further comprises substitutions of: A474V/E558D/T664A/P675L/A678E/E687A/A7410/K813E/R825S/R836H/E870N/I881V/E8 87G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E or K473T/A474V/Q546E/D599EN624L/D637E/K639A/G660R/T664A/Q674K/T715A/A716T/A 741G/A782V/K813E/I824M/E870N/I881V/E8870/D893G/E947K/S954N/M967V/A1008D/D 1019E.
 32. A mutant of CYP102A1 comprises substitutions selected from the group consisting of: R47L/F81I/F87V/E143G/L188Q/E267V (M#16), R47L/E64G/F81I/F87V/E143G/L188Q/E267V (M#17), R47L/L86I/F87V/L188Q/A475V/E559D/T665A/P676L/A679E/E688A/A742G/K814E/R826S/R837H/E871N/I882V/E888G/P895S/S955N/M968V/Q982R/A1009D/H1022Y/Q102 3E (M#13V2), R47L/E64G/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021Y/Q1022E (M#15V3), R47L/F81I/F87V/E1430/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1008D/H1021 Y/Q 1022E (M#16V2), R47L/E64G/F81I/F87V/E143G/L188Q/E267V/A474V/E558D/T664A/P675L/A678E/E687A/A741G/K813E/R825S/R836H/E870N/I881V/E887G/P894S/S954N/M967V/Q981R/A1 008D/H1021Y/Q1022E (M#17V2), and R47L/E64G/F81I/F87V/E143G/L188Q/E267V/K474T/A475V/Q547E/D600E/V625L/D638E/K640A/G661R/T665A/Q675K/T716A/A717T/A742G/A783V/K814E/I825M/E871N/I8 82V/E888G/D894G/E948K/S955N/M968V/A1009D/D1020E (M#17V8).
 33. An isolated nucleic acid encoding the CYP102A mutant of claim
 29. 34. An isolated nucleic acid encoding the CYP102A mutant of claim
 30. 35. An isolated nucleic acid encoding the CYP102A mutant of claim
 31. 36. An isolated nucleic acid encoding the CYP102A mutant of claim
 32. 37. A method of producing human metabolites of simvastatin or lovastatin comprising the steps of reacting the composition of claim 19 with simvastatin or lovastatin.
 38. The method of claim 37, further comprising adding a NADPH-generating system to the reaction.
 39. A kit for producing human metabolites of simvastatin or lovastatin, the kit comprising the composition according to claims 19 and a NADPH-generating system. 